Abstract: BACKGROUND: Ultradian rhythms, rhythms with a period of less than 24 hours, are a widespread and fundamental aspect of life. The mechanisms underlying the control of such rhythms remain only partially understood. Defecation in C. elegans is a very tightly controlled rhythmic process. Underlying the defecation motor programme is an oscillator which functions in the intestinal cells of the animal. This mechanism includes periodic calcium release and subsequent intercellular calcium waves which in turn regulate the muscle contractions that make up the defecation motor programme. Here we investigate the role of TRPM cation channels in this process. RESULTS: We use RNA interference (RNAi) to perturb TRPM channel gene expression. We show that combined knock down of two of the TRPM encoding genes, gon-2 and gtl-1, results in an increase in the variability of the cycle but no change in the mean, in normal culture conditions. By altering the mean using environmental (temperature) and genetic approaches we show that this increase in variability is separable from changes in the mean. We show that gon-2 and gtl-1 interact with components of the calcium signalling machinery (itr-1 the C. elegans inositol 1,4,5-trisphosphate receptor) and with plasma membrane ion channels (flr-1 and kqt-3) which are known to regulate the defecation oscillator. Interactions with these genes result in changes to the mean period and variability. We also show that knocking down a putative transcription factor can suppress the increased variability caused by reduction of gon-2 and gtl-1 function. We also identify a previously unrecognised tendency of the defecation cycle to compensate for cycles with aberrant length by adjusting the length of the following cycle. CONCLUSION: Thus TRPM channels regulate the variability of the defecation oscillator in C. elegans. We conclude that the mean and the variability of the defecation oscillator are separable. Our results support the notion that there is a strong underlying pacemaker which is able to function independently of the observable defecation rhythm and is not perturbed by increases in the variability of the cycle.The interaction of gon-2 and gtl-1 with other components of the oscillator shows that TRPM channels play an important role in the oscillator machinery. Such a role may be through either regulation of cation levels or membrane properties or both. Specifically our results support previous proposals that gon-2 and gtl-1 regulate IP3 signalling and that kqt-3 may act by altering calcium influx.Our results provide novel insights into the properties of the defecation oscillator and thus to our understanding of ultradian rhythms.

Abstract: Migration of cells within epithelial sheets is an important feature of embryogenesis and other biological processes. Previous work has demonstrated a role for inositol 1,4,5-trisphosphate (IP(3))-mediated calcium signalling in the rearrangement of epidermal cells (also known as hypodermal cells) during embryonic morphogenesis in Caenorhabditis elegans. However the mechanism by which IP(3) production is stimulated is unknown. IP(3) is produced by the action of phospholipase C (PLC). We therefore surveyed the PLC family of C. elegans using RNAi and mutant strains, and found that depletion of PLC-1/PLC-epsilon produced substantial embryonic lethality. We used the epithelial cell marker ajm-1::gfp to follow the behaviour of epidermal cells and found that 96% of the arrested embryos have morphogenetic defects. These defects include defective ventral enclosure and aberrant dorsal intercalation. Using time-lapse confocal microscopy we show that the migration of the ventral epidermal cells, especially of the leading cells, is slower and often fails in plc-1(tm753) embryos. As a consequence plc-1 loss of function results in ruptured embryos with a Gex phenotype (gut on exterior) and lumpy larvae. Thus PLC-1 is involved in the regulation of morphogenesis. Genetic studies using gain- and loss-of-function alleles of itr-1, the gene encoding the IP(3) receptor in C. elegans, demonstrate that PLC-1 acts through ITR-1. Using RNAi and double mutants to deplete the other PLCs in a plc-1 background, we show that PLC-3/PLC-gamma and EGL-8/PLC-beta can compensate for reduced PLC-1 activity. Our work places PLC-epsilon into a pathway controlling epidermal cell migration, thus establishing a novel role for PLC-epsilon.

Abstract: The genome of the nematode Caenorhabditis elegans is unusual among eukaryotes, in that it contains operons. Approximately 15% of genes in the worm are clustered into groups of between two and eight genes, which are under the control of shared regulatory sequences. Polycistronic transcripts from such operons are trans-spliced, during transcription, to produce mature monocistronic messengers. The C. elegans frataxin gene, frh-1, is encoded in the operon CEOP2232. This is one of the largest operons identified thus far in the C. elegans genome. Here we describe in detail the structure of all of the coding units within this operon. The operon is composed of eight genes of a diverse nature, organized in a complex structure. We have produced transgenic strains carrying fusions between gfp and a number of genes from the operon. These constructs show complex differential expression patterns that suggest the presence of internal promoters and regulatory sequences in the operon. This organization would permit both coordinated expression and differential expression of the components of the CEOP2232 operon. The heterogeneity of the genes, and their complex expression patterns, suggests that the clustering of CEOP2232 is not due to a need for synchronized expression of genes involved in the same physiological pathway.

Abstract: Coenzyme Q (Q) and the genes involved in its biosynthesis are involved in aging and development of Caenorhabditis elegans. Q is synthesized by at least eight highly conserved nuclear coq genes, but this biosynthesis pathway and its regulation is not known. The coq-8 gene sequence has homology to the ABC-1 family kinases and is the only known candidate for a possible regulation of this pathway. To study coq-8 expression pattern, we have developed a C. elegans transgenic strain expressing ubiquinone biosynthesis coq-8 gene promoter and GFP construct. We show here an age-dependent specific pattern from embryo to senescence for COQ-8 protein expression. Expression in embryo was triggered by a defined group of blastomers before morphogenesis. In elderly nematodes expression was only observed in nervous system, whilst expression in larvae was also detected in hypodermis, muscles and coelomocytes. Global expression provide a regulated pattern during life cycle of the nematode.

Abstract: Friedreich ataxia is an autosomal recessive neurological disorder caused by deficiency of the mitochondrial protein frataxin. Studies in patient cells, mouse knockout animals, and Saccharomyces cerevisiae models have suggested several hypotheses on the frataxin function, but the full physiology of frataxin in mitochondria has not been well established yet. We have characterized the genomic structure of frh-1, the Caenorhabditis elegans frataxin gene, and we have developed a transient knockdown model of C. elegans frataxin deficiency by RNA interference. frh-1(RNAi) worms show a consistent pleiotropic phenotype that includes slow growth, lethargic behavior, egg laying defects, reduced brood size, abnormal pharyngeal pumping, and altered defecation. Lifespan is significantly reduced, and worms have increased sensitivity to oxidative stress that, in turn, might explain the reduction of longevity of the worms. We also demonstrate synthetic genetic interaction between frh-1 and mev-1, the gene encoding the succinate dehydrogenase cytochrome b subunit of complex II in mitochondria, suggesting a possible role of the C. elegans frataxin in the electron transport chain; thus, the respiratory chain might be involved in the pathogenesis of the disease. We propose that this C. elegans model may be a useful biological tool for drug screening in Friedreich ataxia.

Abstract: Frataxin deficiency is the main cause of Friedreich ataxia, an autosomal recessive neurodegenerative disorder. Frataxin function in mitochondria has not been fully explained yet. In this work, we show that Saccharomyces cerevisiae frataxin orthologue Yfh1p interacts physically with succinate dehydrogenase complex subunits Sdh1p and Sdh2p of the yeast mitochondrial electron transport chain and also with electron transfer flavoprotein complex ETFalpha and ETFbeta subunits from the electron transfer flavoprotein complex. Genetic synthetic interaction experiments confirmed a functional relationship between YFH1 and succinate dehydrogenase genes SDH1 and SDH2. We also demonstrate a physical interaction between human frataxin and human succinate dehydrogenase complex subunits, suggesting also a key role of frataxin in the mitochondrial electron transport chain in humans. Consequently, we suggest a direct participation of the respiratory chain in the pathogenesis of the Friedreich ataxia, which we propose to be considered as an OXPHOS disease.

Abstract: Friedreich's ataxia is caused by mutations in the FRDA gene that encodes frataxin, a nuclear-encoded mitochondrial protein. Most patients are homozygous for the expansion of a GAA triplet repeat within the FRDA gene, but a few patients show compound heterozygosity for a point mutation and the GAA-repeat expansion. We analyzed DNA samples from a cohort of 241 patients with autosomal recessive or isolated spinocerebellar ataxia for the GAA triplet expansion. Patients heterozygous for the GAA expansion were screened for point mutations within the FRDA coding region. Molecular analyses included the single-strand conformation polymorphism analysis, direct sequencing, and linkage analysis with FRDA locus flanking markers. Seven compound heterozygous patients were identified. In four patients, a point mutation that predicts a truncated frataxin was detected. Three of them associated classic early-onset Friedreich's ataxia with an expanded GAA allele greater than 800 repeats. The other patient associated late-onset disease at the age of 29 years with a 350-GAA repeat expansion. In two patients manifesting the classical phenotype, no changes were observed by single-strand conformation polymorphism (SSCP) analysis. Linkage analysis in a family with two children affected by an ataxic syndrome, one of them showing heterozygosity for the GAA expansion, confirmed no linkage to the FRDA locus. Most point mutations in compound heterozygous Friedreich's ataxia patients are null mutations. In the present patients, clinical phenotype seems to be related to the GAA repeat number in the expanded allele. Complete molecular definition in these patients is required for clinical diagnosis and genetic counseling.

Abstract: The Ty3/gypsy family of retroelements is closely related to retroviruses, and some of their members have an open reading frame resembling the retroviral gene env. Sequences homologous to the gypsy element from Drosophila melanogaster are widely distributed among Drosophila species. In this work, we report a phylogenetic study based mainly on the analysis of the 5' region of the env gene from several species of the obscura group, and also from sequences already reported of D. melanogaster, Drosophila virilis, and Drosophila hydei. Our results indicate that the gypsy elements from species of the obscura group constitute a monophyletic group which has strongly diverged from the prototypic D. melanogaster gypsy element. Phylogenetic relationships between gypsy sequences from the obscura group are consistent with those of their hosts, indicating vertical transmission. However, D. hydei and D. virilis gypsy sequences are closely related to those of the affinis subgroup, which could be indicative of horizontal transmission.